创建固碳、固氮和脱卤黄杆菌基因工具箱

Alexa F. Van Voorhis, Rebecca S. Sherbo
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引用次数: 0

摘要

X. autotrophicus 是一种代谢灵活的微生物,具有两个主要特征:1) 该生物适应在多种碳源上生长,包括 CO2、甲醇、甲酸盐、丙烯、卤代烷烃和卤代酸;以及 2) X. 自养菌是第一个被发现的能同时固定 N2 的化能自养菌,这意味着该生物可以利用 CO2、N2 和 H2 进行生长。这种新陈代谢的灵活性使 X. 自养菌能够用于气体固定、利用气体制造肥料和食品以及环境污染物的脱卤。尽管这种生物的应用范围已经非常广泛,但用于探索和利用其新陈代谢的基因工具却很少。在此,我们报告了一个用于 X. 自养菌的基因工具箱。我们首先确定了合适的复制起源并量化了其拷贝数,还确定了可用作选择性标记的抗生素抗性盒。然后,我们测试了几种组成型和诱导型启动子和终止子,并量化了它们的启动子强度和终止效率。最后,我们证明了基因表达工具在自养和脱卤代谢条件下仍然有效,从而表明这些工具可用于使 X. autotrophicus 独特的环境中。我们对这些工具在自养酵母中的广泛表征将有助于基因和代谢工程优化气体肥料和食品的生产,并实现卤化环境污染物的生物修复。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Creating a genetic toolbox for the carbon-fixing, nitrogen-fixing and dehalogenating bacterium Xanthobacter autotrophicus
X. autotrophicus is a metabolically flexible microorganism with two key features: 1) The organism has adapted to grow on a wide variety of carbon sources including CO2, methanol, formate, propylene, haloalkanes and haloacids; and 2) X. autotrophicus was the first chemoautotroph identified that could also simultaneously fix N2, meaning the organism can utilize CO2, N2, and H2 for growth. This metabolic flexibility has enabled use of X. autotrophicus for gas fixation, the creation of fertilizers and foods from gases, and the dehalogenation of environmental contaminants. Despite the wide variety of applications that have already been demonstrated for this organism, there are few genetic tools available to explore and exploit its metabolism. Here, we report a genetic toolbox for use in X. autotrophicus. We first identified suitable origins of replication and quantified their copy number, and identified antibiotic resistance cassettes that could be used as selectable markers. We then tested several constitutive and inducible promoters and terminators and quantified their promoter strengths and termination efficiencies. Finally, we demonstrated that gene expression tools remain effective under both autotrophic and dehalogenative metabolic conditions to show that these tools can be used in the environments that make X. autotrophicus unique. Our extensive characterization of these tools in X. autotrophicus will enable genetic and metabolic engineering to optimize production of fertilizers and foods from gases, and enable bioremediation of halogenated environmental contaminants.
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